KR20170100015A - Vehicle identification system - Google Patents

Abstract

Disclosed is an identification system that improves on-road safety and permits the vehicle itself to have readable and useful information about road signs, roads and adjacent road information in the case of a driver or vehicle in autonomous or semi-autonomous mode. The disclosed identification system includes a marker having marker communication information that can be read by the vehicle information system to provide information to the vehicle. The information that the marker communication information can convey will allow the vehicle information system to detect or recognize important road signs, road information and adjacent road information, or both detection and recognition. The vehicle information system can then respond to the information received from the marker communication information.

Description

Vehicle identification system

The present invention relates to an identification system. In particular, the present invention relates to an identification system for use in a vehicle, comprising a marker capable of detecting a sign or identifying a sign or both.

Road signs vary in size, shape, image, and the words you want to convey to the driver. For example, many signs have similar outer shapes but convey different messages or images. Images on a sign such as an arrow can convey different meanings depending on other features on the sign. For example, a sign with arrows of the same size and color may indicate the direction of the destination, whereas a sign with arrows represents a "one way" road. It may be difficult to identify and distinguish important road signs with the ability to provide important information for safe vehicle operation from a wide variety of signs with similar shapes.

Available electronic and communication capabilities can help identify and communicate between road signs and vehicles. In particular, camera-based visual systems are becoming popular in new vehicles. However, current visual systems typically have difficulty in accurately reading a wide range of highway signs. For example, as discussed, a reader may be able to identify the arrow, but may not be able to correctly identify the context that identifies whether the arrow is a "one-way" sign or a direction to a destination. There is a need for an improved identification system for more precise detection or recognition of important road signs, road information and adjacent road information, or both detection and recognition.

Disclosed is an identification system that improves on-road safety and allows the driver or the vehicle itself (in the case of an autonomous or semi-autonomous vehicle) to have readable and useful information about road signs, roads and adjacent road information. The disclosed identification system includes a marker having marker communication information that can be read by the vehicle information system to provide information to the vehicle. The information with which the marker communication information can communicate allows the vehicle information system to detect or recognize important road signs, road information and adjacent road information, or both detection and recognition. The vehicle information system can then respond to the information received from the marker communication information.

In one embodiment, the identification system includes a vehicle information system on the vehicle, including a marker having marker communication information, and a processor for reading the marker communication information and a processor for converting the marker communication information into output information.

In one embodiment, the marker for transmitting information to the vehicle includes marker communication information, which is static information, and the marker communication information is information that can convert the reader and marker communication information on the vehicle ' s vehicle information system to output information And transmitted to the processor.

In one embodiment, the vehicle information system includes a reader and a processor. The reader may receive marker communication information from the marker. The processor may convert the marker communication information into output information.

In one embodiment, the identification system between the sign and the vehicle may include a sign with sign communication information, a marker-marker at a predetermined location for the sign includes marker communication information including optical communication, A reader that reads optical communication, and a vehicle information system that includes a processor that converts optical communication to output information. The optical communication of the marker is retroreflected light from the light source. The output information is at least one of the detection of the presence of the sign or the recognition of the sign communication information.

In one embodiment, the marker for a sign with sign communication information includes marker communication information including optical communication, which is light reflected from a retroreflective sheet and a retroreflective sheet. The marker is in a predetermined position relative to the sign. The marker communication information communicates information about the position of the sign and the sign communication information.

In general, the sign communication information may be any text or graphic intended to provide information to the road user or a combination thereof. Optical communication is based on communications based on patterns (e.g., machine-readable text, graphics, indicia, patterns, shapes, or codes such as barcodes or QR codes) read using visible or invisible wavelengths But includes communication based on changes or patterns of properties such as frequency, wavelength, polarization, or amplitude including pulse amplitude.

In any one of the described embodiments, the identification system further comprises any one of the following:

표지판 통신 정보를 갖는 표지판.

Signs Signs with communication information.

출력 정보는 표지판의 존재의 검출 또는 표지판 통신 정보의 인식 중 적어도 하나임.

The output information is at least one of the detection of the presence of the sign or the recognition of the sign communication information.

마커는 표지판에 대해 미리결정된 위치에 있음.

The marker is in a predetermined position for the sign.

마커는 표지판에 부착됨.

The marker is attached to the sign.

마커는 표지판에 접착식으로 장착됨.

The markers are adhesively mounted on the sign.

마커는 표지판 내에 매립됨.

The marker is embedded in the sign.

마커는 표지판으로부터 분리되어 있는 것으로서, 이동하는 차량의 방향에 대해 표지판에 선행함.

The markers are separated from the signs, preceded by signs for the direction of the moving vehicle.

출력 정보는 표지판과의 거리임.

The output information is the distance from the sign.

마커 통신 정보는 정적 정보임.

The marker communication information is static information.

정적 정보는 코드임.

Static information is code.

정적 정보는 광학 이미지임.

Static information is an optical image.

정적 정보는 전자 신호임.

Static information is electronic signals.

마커는 수동 통신 디바이스를 포함함.

The marker includes a passive communication device.

마커에 광을 송신하기 위한 광원.

A light source for transmitting light to a marker.

마커 통신 정보는 광학 통신을 포함함.

The marker communication information includes optical communication.

마커 통신 정보는 재귀반사된 광을 포함함.

The marker communication information includes retroreflected light.

마커 통신 정보는 특정 파장의 반사된 광을 포함함.

The marker communication information includes reflected light of a specific wavelength.

마커 통신 정보는 적외선(IR) 또는 근적외선(near-IR) 광을 포함함.

The marker communication information includes infrared (IR) or near-IR light.

마커는 재귀반사성 필름을 포함함.

The markers include retroreflective films.

재귀반사성 필름은 광원으로부터의 광을 판독기에 대해 특정 각도로 반사함.

A retroreflective film reflects light from a light source at a specific angle relative to the reader.

마커는 다층 광학 필름을 포함함.

The markers include multilayer optical films.

다층 광학 필름은 광원의 하나 이상의 특정 파장을 판독기로부터 멀어지게 반사함.

The multilayer optical film reflects at least one specific wavelength of the light source away from the reader.

다층 광학 필름은 광원의 적외선 또는 근적외선 파장을 판독기로부터 멀어지게 반사함.

The multilayer optical film reflects the infrared or near infrared wavelengths of the light source away from the reader.

다층 광학 필름은 코드를 포함함.

The multilayer optical film includes a cord.

코드는 바코드 또는 QR 코드임.

The code is a bar code or QR code.

마커는 판독기가 볼 수 있는 파장-특정 잉크를 포함함.

The marker includes a wavelength-specific ink that the reader can see.

마커는 에너지 소스를 갖는 능동 통신 디바이스를 포함함.

The marker includes an active communication device having an energy source.

마커 통신 정보는 전자 신호를 포함함.

The marker communication information includes an electronic signal.

전자 신호는 펄스 발광 다이오드 신호, 청각 신호, 무선 신호 중 하나를 포함함.

The electronic signal includes one of a pulsed light emitting diode signal, an audible signal, and a radio signal.

마커 통신 정보는 포지션(position) 정보를 포함함.

The marker communication information includes position information.

차량 정보 시스템은 광원을 더 포함함.

The vehicle information system further includes a light source.

광원은 특정 범위의 파장에서 광을 방출함.

A light source emits light at a specific range of wavelengths.

광원으로부터 방출되는 광의 특정 범위의 파장은 사람의 눈에 가시적인 파장의 범위 밖에 있음.

The wavelength of a particular range of light emitted from the light source is outside the range of wavelengths visible to the human eye.

광원으로부터 방출되는 광의 특정 범위의 파장은 근적외선임.

The wavelength of the specific range of light emitted from the light source is near infrared.

마커는 미리결정된 형상, 색 또는 재귀반사성 속성을 포함함.

The markers include predetermined shape, color, or retroreflective properties.

마커는 미리결정된 재귀반사성 발산 프로파일 또는 재귀반사된 광의 편광 변화를 포함함.

The marker includes a predetermined retroreflective divergence profile or a polarization change of the retroreflected light.

차량 정보 시스템은 수신되는 마커 통신 정보로부터 마커를 식별함.

The vehicle information system identifies the marker from the received marker communication information.

판독기는 특정 범위의 파장에서 마커 통신 정보를 수신함.

The reader receives marker communication information at a specific range of wavelengths.

마커 통신 정보의 특정 범위의 파장은 사람의 눈에 가시적인 파장의 범위 밖에 있음.

The wavelength of a specific range of marker communication information is outside the range of wavelengths visible to the human eye.

마커 통신 정보의 특정 범위의 파장은 적외선 또는 근적외선임.

The wavelength of a specific range of marker communication information is infrared or near-infrared.

차량 정보 시스템의 판독기는 마커 통신 정보를 수신하기 위한 렌즈를 포함함.

The reader of the vehicle information system includes a lens for receiving marker communication information.

차량 정보 시스템의 판독기는 마커 통신 정보를 수신하기 위한 렌즈를 갖는 카메라를 포함함.

The reader of the vehicle information system includes a camera having a lens for receiving marker communication information.

차량 정보 시스템의 판독기는 마커로부터 전자 신호를 수신함.

The reader of the vehicle information system receives the electronic signal from the marker.

차량 정보 시스템의 판독기는 청각 신호를 수신함.

The reader of the vehicle information system receives the audible signal.

차량 정보 시스템의 판독기는 무선 신호를 수신함.

The reader of the vehicle information system receives the radio signal.

차량 정보 시스템의 판독기는 광원으로부터 신호를 수신함.

The reader of the vehicle information system receives the signal from the light source.

차량 정보 시스템의 판독기는 광원으로부터 적어도 부분적으로 재귀반사된 광인 광학 통신을 수신함.

The reader of the vehicle information system receives optical communication, which is at least partially retroreflected light from the light source.

프로세서는 인터넷 기반 정보 저장 시스템과 통신함.

The processor communicates with an Internet-based information storage system.

인터넷 기반 정보 저장 시스템은 마커 통신 정보를 수신하고 포괄적인 정보를 프로세서에 제공함.

An Internet-based information storage system receives marker communication information and provides comprehensive information to the processor.

포괄적인 정보는 표지판 통신 정보, 지리적 배치 정보, 기상 정보, 교통 정보, 지역 비즈니스 정보, 뉴스 정보, 또는 인접 배치된 고정물들을 포함함.

Comprehensive information includes signage communication information, geographical positioning information, weather information, traffic information, local business information, news information, or adjacently located fixtures.

인접 배치된 고정물들은 차량, 식당, 사업장으로 이루어진 군으로부터 선택됨.

Adjacent fixtures are selected from the group consisting of vehicles, restaurants, and workplaces.

마커 통신은 표지판 통신에 관한 정보를 포함함.

Marker communication includes information about sign communication.

출력 정보는 차량의 동작을 제어하는데 사용됨.

The output information is used to control the operation of the vehicle.

출력 정보는 표지판의 존재의 검출 및 표지판 통신 정보의 인식임.

The output information is the detection of the presence of the sign and the recognition of the sign communication information.

1 is a plan view of one embodiment of an identification system.
While the identified figures and configurations describe embodiments of the present invention, other embodiments are also contemplated as discussed in the discussion. In all instances, the present disclosure is intended to be illustrative, not limiting. Many other modifications and embodiments may be devised by those skilled in the art, and it is to be understood that this is within the scope and spirit of the invention. The drawings may not be drawn to scale.

The identification system 100 includes a marker 300 that includes marker communication information that can be read by the vehicle information system. 1 is a plan view of a road 700 in which the vehicle 600 travels in the direction of the arrow. There is a marker 300 that includes marker communication information adjacent to the road. Further, a sign 200 including sign communication information such as "STOP" or a right turn arrow is illustrated in FIG. In one embodiment, the marker communication information may communicate information about the sign communication information. In one embodiment, the marker communication information may communicate important road signs, road information, and information about adjacent road information. On the vehicle 600 is a vehicle information system 400 for reading and processing the marker communication information.

It would be costly and time consuming to completely redesign existing road signs to include information that is more readable by the vehicle's reader. Thus, the disclosed identification system 100 includes a marker 300 that separately includes the marker communication information. In one embodiment, the marker 300 may be affixed to the sign 200 or a post that holds the sign. For example, the markers 300 may be attached during the initial construction of the sign 200, or may be separately attached to the existing signboard 200 already completed. When attached during the initial construction of the sign 200, the markers 300 can be embedded in the sign 200. [ When attached to the completed sign 200, the markers 300 may be adhesively secured to the sign 200. [ When the identification system 100 relies on the optical identification of the marker communication information of the marker 300, the marker 300 is attached to the visible surface or visible portion of the sign 200.

In one embodiment, the marker 300 is not attached or connected to any portion of the sign 200. Instead, the marker 300 is located near the road 700. When the identification system 100 relies on the optical identification of the marker communication information of the marker 300, the marker 300 is placed at a visible location near the road 700. [ The marker 300 itself may look like a sign. The marker 300 may be secured on its own post to other road fixtures, adjacent fixtures, or underground posts.

To provide additional data to the vehicle information system 400, in one embodiment, the marker 300 is in a predetermined position relative to the sign 200. [ In one embodiment, the marker 300 is located on a sign. Typically, when the marker 300 is separated from the sign 200, the marker 300 will precede the sign 200 with respect to the direction of the moving vehicle, as illustrated in FIG. The marker 300 may also be displaced from the sign 200 and placed on a sign post or other support structure. If the marker 300 is in a predetermined position with respect to a sign 200, such as a stop sign, the vehicle information system 400 may be used to calculate such things as the time to stop before the sign or the direction the vehicle should turn after the sign , The position information of the marker 300 for the sign 200 can be used together with any other input.

The marker 300 includes marker communication information. The marker communication information is information that the marker 300 communicates to the vehicle information system 400, and the vehicle information system reads and processes the marker communication information (details of the vehicle information system 400 are described below).

In one embodiment, the marker 300 further comprises a passive communication device. The passive communication device is a device that includes marker communication information that can be read, and the marker communication information does not change. Thus, in this embodiment, the marker communication information includes unchanging information, i.e., static information. In one embodiment, the static information includes optical communications, such as, for example, machine-readable text, graphics, labels, patterns, shapes, or codes such as bar codes or QR codes.

Depending on the marker functionality, the marker 300 may require a power source that may be provided from elements such as batteries, solar panels or electrical connections. To limit the demand for power consumption or battery monitoring and modification, the preferred marker 300 functions without an external power source.

In embodiments in which the marker communication information includes optical communication, the optical communication may be light reflected from a source illuminating the marker. To reflect light, the marker 300 may comprise a reflective and / or a retroreflective material. The term "reflective ", as used herein, refers to the property of reflecting light that is obliquely incident at the same angle measured relative to the surface normal of the marker, and the incident and reflected light and surface normals are coplanar Mirror reflection surface). The term " retroreflective ", as used herein, refers to an attribute that reflects, or nearly does, an obliquely incident ray in a direction antiparallel to the direction of its incidence, such that the ray either returns to the immediate vicinity of the light source or light source do. The incidence direction is typically angularly displaced from the surface normal of the sign or marker by the angle of incidence. Preferably, the returned light is angularly displaced by an observation angle from its incidence direction so that it can be read by a detector displaced from the source (e.g., the eyes of a person displaced relative to the vehicle headlight). Both incidence and observation are varied as a function of the vehicle position for the sign or marker. Two known types of retroreflective sheeting are microsphere-based sheets and cube corner sheets (often referred to as prismatic sheets). A microsphere-based sheet, often referred to as a "bead-shaped" sheet, is typically at least partially embedded within the binder layer to retroreflect incident light and includes an associated mirror or diffuse reflective material (e.g., pigment particles, metal flakes, ). ≪ / RTI > Illustrative examples are described, for example, in U.S. Patent 3,190,178 (McKenzie), 4,025,159 (McGrath), and 5,066,098 (Kult). Cube corner retroreflective sheeting, commonly referred to as a "prismatic" sheet, includes a body portion typically having a substantially planar front surface and a structured rear surface comprising a plurality of cube corner elements. Each cube corner element includes three optical surfaces that are approximately mutually perpendicular. Illustrative examples include, for example, those described in U.S. Patent Nos. 1,591,572 (Stimson), 4,588,258 (Hoopman), 4,775,219 (Appledorn et al.), 5,138,488 Szczech), and 7,261, 426 (Smith et al.). The sealing layer may be applied to the structured surface to remove contaminants from individual cube corners. For example, flexible cube corner sheets such as those described in U.S. Patent No. 5,450,235 (Smith et al.) May be included in embodiments or implementations of the present application. The retroreflective sheeting for use in connection with the present application may be, for example, matte or glossy.

Retroreflective films can be designed in a manner that retroreflects light transmitting different optical communications, for example as a function of incident or viewing angles. For example, the vehicle 600, 300 meters away from the retroreflective marker 300, may retroreflect the light providing the first optical signal to the vehicle information system 400, The separated vehicle 600 may retroreflect the light that provides the second optical signal to the vehicle information system 400. [ For example, for a retroreflective film used as the marker 300, if the reader 420 is at 0.35 meters from the light source 410 of the vehicle information system 400, It is 1.0 degree in the meter.

In some embodiments, the reflected light of the marker communication information may be light of a particular wavelength. For example, the marker communication information may include infrared or near infrared light. Infrared or near-infrared optical communication will not be noticeable in the visible light spectrum and therefore will not cause visual distraction to the driver of the vehicle 600.

In embodiments where the marker communication information includes optical communication with light of a particular wavelength, the marker 300 may include a layer for controlling the reflected light. In one embodiment, the marker 300 comprises a multilayer optical film to control the reflected light. In one embodiment, the marker 300 comprises a wavelength-specific ink.

For example, the markers 300 may include one or more visibly transparent, near-infrared reflective multilayer optical films permanently or temporarily attached to the retroreflective sheeting. This attachment may occur, for example, by use of an adhesive. Using the region of the transparent reflective multilayer optical film that is visibly transparent on the marker 300 causes the light of a particular wavelength, such as near infrared light incident on the marker 300, to otherwise reflect from a retroreflective optical path, Produces a region of high contrast as compared to the adjacent region on the marker 300 without the multilayer optical film when viewed. The specific wavelength is reflected away from the vehicle information system 400 to read the marker communication information. Multilayer optical films are wavelength-specific reflective mirrors that effectively have high transmissivity in different wavelength regions, such as the visible portion of the wavelength spectrum. On the other hand, the image / graphic / mark / pattern on the marker 300 is maintained substantially unaffected by the presence of the multilayer optical film (s) when viewed as visible light. Since the visibly transparent wavelength-specific reflective multilayer optical film (s) are not noticeable in the visible portion of the wavelength spectrum, the image / graphic / mark / pattern generated using the multilayer optical film (s) And is not visible to the human eye and does not cause visual distraction to the driver.

The multilayer optical film selected for any particular implementation will depend on the desired optical, structural, and durability characteristics. As such, the preferred multilayer optical film will vary based on the intended application. Some exemplary multilayer optical films are described, for example, in U.S. Patent No. 6,024,455 and PCT Publication No. WO 95/17692. Exemplary commercially available multilayer optical films include, for example, Vikuiti Clear Card Filter, Solar Reflective Film, manufactured by 3M Company, St. Paul, Film) and SM 857 (SM 857). The reflection and transmission spectra of a particular multilayer optical film depend in part on the optical thickness of the individual layers along the various axes and are substantially determined by the Fresnel coefficients. The film may be designed to reflect infrared light, visible light, or ultraviolet light by selecting an appropriate optical thickness. The desired relationship between the refractive indexes of the polymer layers can be achieved by selection of suitable materials and appropriate processing conditions.

Alternatively, or in combination, a wavelength-specific dye can be used to provide marker communication information (e.g., infrared reflective or absorbing dye). An exemplary description of such a dye can be found, for example, in U.S. Publication No. 2007/0082963. Commercially available infrared reflective dyes are described, for example, in H.W. H. W. Sands Corporation, and Epolin Corporation, Newark, NJ, USA. One exemplary advantage of using multilayer optical films, particularly multilayer optical films with high visible light transmittance, is that coloration or color change can be largely avoided or minimized, unlike near infrared absorbing dyes.

In one embodiment, the marker 300 further includes an active communication device. An active communication device is a device that can read information, and is a device that includes information that can be read. In an active communication device, the information may change in certain situations. The marker communication in an active communication device includes dynamic information. In one embodiment, the marker communication information is dynamic information including at least one of an optical signal, an audio signal, an electronic signal, and a wireless signal. In one embodiment, the electronic signal is a pulsed light emitting diode signal. In one embodiment, the marker communication in the active communication device is, for example, position or position service information that can supplement the vehicle-based GPS position information. Typically, an active communication device will have an energy source such as a battery.

In one embodiment, the marker 300 includes one or more materials or devices for providing marker communication information. In one embodiment, the marker 300 includes both a passive communication device and an active communication device. In one embodiment, both static information and dynamic information are provided from the marker 300 to the vehicle information system 400 as marker communication information.

The vehicle information system 400 includes a reader 420 and a processor 430. The reader is any type of device capable of detecting marker communication information. A processor is any type of device capable of converting marker communication information into output information. Certain aspects of the reader 420 will be determined based on the format of the marker communication information. In one embodiment, the reader 420 may receive one or more of an optical signal, an electronic signal, an audible signal, a radio frequency signal, or an Internet based signal from the marker 300.

In order for the vehicle information system 400 to read the marker communication information, the vehicle information system 400 first needs to identify the marker 300. In one embodiment, the marker 300 includes a predetermined retroreflective divergence profile or a predetermined shape including a change in the polarization of the recursively reflected light designed to be recognized by the reader 420 and the processor 430, a predetermined color, or a predetermined recursion Reflective properties. The predetermined color may include non-visible light wavelengths. In one embodiment, the vehicle information system 400 identifies the marker 300 from information received by reading and processing the marker communication information. In one embodiment, the vehicle information system 400 identifies the markers 300 by matching predetermined attributes, such as the shape, color, or retroreflectivity properties of the markers 300, using image or text recognition software.

In one embodiment, the reader 420 of the vehicle information system 400 includes a camera for receiving marker communication information. In one embodiment, the reader 420 of the vehicle information system 400 includes a camera with a lens for receiving marker communication information. In one embodiment, the reader 420 of the vehicle information system 400 includes a camera with a lens and a wavelength-sensitive filter for receiving marker communication information. In one embodiment, the reader 420 receives marker communication information at a particular range of wavelengths that may be outside the visible wavelength range of the human eye. In one embodiment, the wavelength of the particular range of marker communication information received by the reader 420 is infrared or near infrared.

The reader 420 will match the functionality of the marker communication information of the marker 300. For example, if the marker communication information is optical communication, the reader 420 would include a camera and a lens; If the marker communication information is optical communication within a certain wavelength range, the reader 420 will include a wavelength-specific camera and lens; If the marker communication information is a wireless signal, the reader 420 will include a wireless reader; If the marker communication information is an RFID signal, the reader 420 will include an RFID reader. It is understood that the marker communication information may include one or more types of information, and therefore the reader 420 may have one or more capabilities for reading the marker communication information.

In the case of optical communication in marker communication information, ambient light may be used as the light source to provide reflected light to the reader 420. However, typically, the vehicle information system 400 includes a light source 410 that directs light to the marker 300 to take particular advantage of the retroreflective properties of the marker. In one embodiment, the light source 410 emits light to the marker 300. In one embodiment, the light source 410 emits light to the marker 300 at a specific range of wavelengths. In one embodiment, the wavelength of a particular range of light emitted from the light source 410 is outside the range of wavelengths visible to the human eye. In one embodiment, the light of a certain range of wavelengths emitted from the light source is near infrared.

The vehicle information system 400 includes a processor 430 for interpreting the marker communication information received by the reader 420 and converting it into output information. Processor 430 includes a common computer processor element, such as a memory. In one embodiment, the processor 430 includes software code for interpreting the marker communication information. In one embodiment, the processor 430 includes pattern recognition or optical character recognition software. The processor 430 may control the transmitter and the receiver and may transmit and receive information such as output information from the vehicle information system 400 to an external device. For example, the processor 430 may transmit the output information to the Internet-based information storage system, which in turn transmits comprehensive information to the processor 430 in association with the output information.

The vehicle information system 400 receives marker communication information from the marker 300 to the vehicle 600. In one embodiment, the vehicle 600 includes a vehicle information system 400 that reads the marker communication information and processes the marker communication as output information. The processed output information may provide visual or auditory information to the driver or may control the function of the vehicle 600. [

In some embodiments, information such as GPS or other position information may be received in the vehicle information system 400, which may cause certain received marker communication information to be irrelevant. For example, information about the lane the car is driving can make some road signs more or less relevant. For example, when the car is traveling in the center lane, the "Exit Only" sign is irrelevant and the vehicle information system can be programmed to ignore the marker communication information.

In one embodiment, the vehicle information system 400 includes a transmission source, such as a light source 410, which first sends signals such as light, audio, electrical or radio signals to the marker 300. The vehicle information system 400 then reads the returned marker communication information and processes the marker communication as output information.

The marker 300 functions to transmit marker communication information from the marker 300 to the vehicle 600. The marker 300 may be read by the reader 420 of the information system 400 to provide visual or auditory information to the driver or may be processed as output information capable of controlling the function of the vehicle 600. In one embodiment, An optical communication, an audio signal, an electrical signal, a wireless signal, and an Internet-based signal. In one embodiment, the marker 300 receives signals such as optical, audio, electrical, wireless, and Internet based from the vehicle information system 400. The marker 300 then responds to the vehicle information system 400 with marker communication information.

The marker communication information may provide the vehicle information system 400 with information on sign communication information, other important adjacent road signs, road information, or adjacent road information.

In one embodiment, the output information from the information stored in the vehicle information system 400 is matched so that the function is applied by the processor 430. For example, the marker communication information may provide information that there is a "stop" sign 100 meters ahead. Processor 430 may match any number of functions, such as an audio message that speaks to the driver as "Stop Ahead ", or processor 430 may control braking of vehicle 600. [

In one embodiment, the output information is transmitted to an Internet-based information storage system. Based on the transmitted information, the Internet-based information storage system may provide comprehensive information, which may include local weather, local traffic conditions, adjacent deployed fixtures (e.g., vehicles, homes, restaurants or businesses), and upcoming road signs, To the processor 430 in the memory 400. For example, the marker communication information may be a code that is deciphered and that includes a static IP address or URL for an Internet-based storage system. The processor 430 may communicate this comprehensive information to the driver of the vehicle 600. The processor 430 may use this generic information to control aspects of the vehicle 600.

For example, if the marker communication information is an optical communication that is read by a camera in the vehicle information system 400, the processor processes the optical communication as output information, which is location information, and sends the output information to an Internet- Can be transmitted. Based on the location information, the Internet-based information storage system can provide comprehensive information, which may include local weather, local traffic conditions, adjacently located fixtures (e.g., vehicles, homes, restaurants or businesses), and upcoming road signs, 400 to the processor 430 within the network. The processor 430 may communicate this comprehensive information to the driver of the vehicle 600. The processor 430 may use this generic information to control aspects of the vehicle 600. For example, processor 430 may control the braking of vehicle 600 if the comprehensive information received from the Internet-based information storage system to processor 430 indicates that there is a pause indication within 100 meters.

Processor 430 may also receive position information to identify a particular marker so that marker communication information received from a particular marker may be linked to specific information from an Internet-based information storage system. For example, if the marker communication information is received at a known location that is information related to a nearby hotel, the marker communication information may be updated to include vacant information for the hotel. For example, if marker communication information is received for a work area, new changes, attention messages, or bypass paths may be communicated to that location.

While specific embodiments of the invention have been illustrated and described herein, it should be understood that these embodiments are merely illustrative of the many possible specific arrangements that may be devised in applying the principles of the invention. Numerous other various arrangements can be devised by those skilled in the art without departing from the spirit and scope of the invention. Accordingly, the scope of the present invention should not be limited to the configurations described in this application, but only by the configurations described in the language of the claims and their equivalents.

Claims (36)

An identification system between a sign and a vehicle,
A sign with sign communication information;
A marker at a predetermined location relative to the sign, the marker comprising marker communication information comprising optical communication; And
A vehicle information system including a light source for transmitting light to the marker, a reader for reading the optical communication, and a processor for converting the optical communication to output information,
Wherein the optical communication of the marker is retroreflected light from the light source;
Wherein the output information is at least one of detection of the presence of the sign or recognition of the sign communication information.
The identification system of claim 1, further comprising a sign having sign communication information.
3. The method of claim 1 or 2, wherein the output information comprises: (i) detecting the presence of the sign; (ii) recognition of the sign communication information; (iii) the distance to the sign; (iv) URL code; (v) information received from an Internet-based information storage system.
The identification system according to any one of claims 1 to 3, wherein the marker is attached to the sign.
5. The identification system according to any one of claims 1 to 4, wherein the marker is separated from the signboard and precedes the signboard with respect to the direction of the moving vehicle.
6. The identification system according to any one of claims 1 to 5, wherein the marker communication information is static information.
7. An identification system according to any one of claims 1 to 6, wherein the static information is one of a code, an optical image and an electronic signal.
8. An identification system according to any one of claims 1 to 7, wherein the marker further comprises a passive communication device.
9. The identification system according to any one of claims 1 to 8, further comprising a light source for transmitting light to the marker.
10. An identification system according to any one of claims 1 to 9, wherein the light emitted from the light source is outside the range of wavelengths visible to the human eye.
11. An identification system according to any one of claims 1 to 10, wherein the light emitted from the light source is near-IR.
12. An identification system according to any one of claims 1 to 11, wherein the marker communication information is a predetermined indicia.
13. An identification system according to any one of the preceding claims, wherein the marker communication information comprises retroreflected light.
14. An identification system according to any one of the preceding claims, wherein the marker communication information comprises reflected light of a particular wavelength.
15. An identification system as claimed in any one of the preceding claims, wherein the marker comprises a retroreflective film reflecting light from the light source at a certain angle relative to the reader.
16. An identification system according to any one of claims 1 to 15, wherein the marker comprises a multilayer optical film that reflects at least one particular wavelength of the light source away from the reader.
17. An identification system according to any one of the preceding claims, wherein the marker comprises wavelength-specific ink visible to the reader.
18. An identification system according to any one of the preceding claims, wherein the marker further comprises an active communication device having an energy source.
19. An identification system as claimed in any one of claims 1 to 18, wherein the marker communication information further comprises an electronic signal comprising a pulse light emitting diode signal, an audible signal, and a radio signal.
20. An identification system according to any one of claims 1 to 19, wherein the marker communication information comprises position information.
21. An identification system according to any one of claims 1 to 20, wherein the marker comprises a predetermined shape, color or retroreflective attribute.

22. An identification system according to any one of the preceding claims, wherein the marker comprises a predetermined retroreflective divergence profile or a polarization change of the retroreflected light.
23. An identification system as claimed in any one of the preceding claims, wherein the vehicle information system receives marker communication information and identifies the marker therefrom.
24. An identification system as claimed in any one of claims 1 to 23, wherein the processor receives position information relating to the position of the vehicle, and wherein the position information causes the processor to ignore specific marker communication information.
25. An identification system according to any one of the preceding claims, wherein the reader receives the marker communication information at a specific range of wavelengths.
26. An identification system according to any one of claims 1 to 25, wherein the wavelength of the specific range of the marker communication information is outside the range of wavelengths visible to the human eye.
27. The vehicle information system of any one of claims 1 to 26, wherein the reader of the vehicle information system further receives at least one of an electronic signal from the marker, an audible signal from the marker, or a signal from the light source, system.
28. An identification system as claimed in any one of claims 1 to 27, wherein the reader of the vehicle information system receives the optical communication, the light being at least partially retroreflected from the light source.
29. The system of any one of claims 1 to 28, wherein the processor is in communication with an Internet-based information storage system.
30. The system of claim 29, wherein the Internet-based information storage system receives marker communication information and provides comprehensive information to the processor.
30. The system of claim 29, wherein the Internet-based information storage system receives position information associated with received marker communication information and provides comprehensive information about the particular marker to the processor.
32. The system of claim 30 or 31, wherein the comprehensive information comprises signage communication information, geographical location information, weather information, local business information, news information, traffic information, and adjacently located fixtures.
33. An identification system as claimed in any one of claims 30 to 32, wherein the comprehensive information received from the Internet based information storage system is dynamic information for a particular marker.
34. An identification system according to any one of claims 1 to 33, wherein the output information is used to control the operation of the vehicle.

35. The identification system according to any one of claims 1 to 34, wherein the output information is the detection of the presence of the sign and the recognition of the sign communication information.
Marker A marker for a sign having communication information,
Retroreflective sheet; And
And marker communication information including optical communication that is light reflected from the retroreflective sheet,
Wherein the marker is in a predetermined position with respect to the sign,
Wherein the marker communication information communicates information about the position of the sign and the sign communication information.

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